Micro-bubble generator

ABSTRACT

A micro-bubble generator is provided between an input end and an output end of a water outlet device. The micro-bubble generator includes a water inlet member and a water outlet member. A gas inlet gap is remained between the water inlet member and the water outlet member, with the gas inlet gap being communicated to external air, such that the external air is allowed to enter the micro-bubble generator for gas-liquid mixing and generate minute and dense bubbles.

FIELD OF THE INVENTION

The present invention is related to a micro-bubble generator,particularly to a micro-bubble generator being provided on a wateroutlet device as well as capable of increasing gas content of waterstream and degree of miniaturization of bubbles.

BACKGROUND OF THE INVENTION

An existing aerator is primarily composed of a pump, a water outlet pipeand a gas-liquid mixing pipe. In the structure of the aerator, thevolume of bubble of water stream being flowing through the gas-liquidmixing pipe is determined by the capacity of a gas inlet pipe and waterpressure of the pump. Further, it is necessary for the water pressure ofthe pump to maintain the water stream to achieve a flow rate over acertain level, so as to form gas-liquid mixing. Thus, it is impossiblefor a user to change the average volume of bubbles generated within thegas-liquid mixing pipe arbitrarily. If finer bubbles are required by theuser for water purification, this requirement will not be met by theexisting aerator. In addition, the gas content of the liquid-gas mixingliquid generated by the existing bubble mixing device is too low togenerate water-gas mixing liquid containing a large amount of densebubbles in milky-white color. Thus, how to eliminate the drawbacks ofexisting technology described above is truly the problem to be overcomeby the industry desirably.

SUMMARY OF THE INVENTION

It is one object of the present invention to eliminate drawbacks ofinsufficient gas content and bubble density and etc., of the existingliquid-gas mixing device.

For achieving the above object, the present invention provides amicro-bubble generator located between an input end and an output end ofa water outlet device. The micro-bubble generator includes a water inletmember and a water outlet member. The water inlet member includes afirst main body adjacent to the input end, and a first channelpenetrating the first main body, the first main body being provided atone end penetrated by the first channel with a first junction surface.The water outlet member includes a second main body adjacent to theoutput end, and a second channel penetrating the second main body, thesecond main body being provided at one end penetrated by the secondchannel with a second junction surface. In this manner, the water inletmember and the water outlet member are abutted against each other, withthe first junction surface facing the second junction surface, the firstchannel being communicated with the second channel, and the engagementbetween the first junction surface and the second junction surfaceremaining a gas inlet gap, the gas inlet gap communicating external airto the first channel and the second channel.

Furthermore, the water inlet member includes a plurality of firstbranching channels arranged alongside of the first channel, while thewater outlet member includes a plurality of second branching channelsarranged alongside of the second channel. Moreover, the engagementbetween the first branching channel and the second branching channel iscommunicated with the gas inlet gap.

Furthermore, the water inlet member, on one side adjacent to the inputend, includes a raised platform penetrated by the first channel, and anotch depressed around the raised platform and penetrated by each firstbranching channel.

Furthermore, each first branching channel and/or each second branchingchannel may be inclined with respect to the first channel and the secondchannel, respectively.

Furthermore, the micro-bubble generator further includes a sleeve and anair vent perforation penetrating the sleeve. The water inlet member andthe water outlet member may be put into the sleeve and fixed, while thegas inlet gap is communicated with the air vent perforation.

Furthermore, the micro-bubble generator further includes an eddy currentguiding pipe located at one end, adjacent to the second main body, ofthe sleeve, the eddy current guiding pipe including a plurality ofblades in a spiral manner, a plurality of eddy current passages, whereineach of the plurality of eddy current passages is arranged between twoof the plurality of blades, and an outer casing tube surrounding theplurality of blades and the plurality of eddy current passages, aplurality of stepped surfaces being provided on a surface of each of theplurality of blades corresponding to each of the plurality of eddycurrent passages.

Furthermore, the water outlet member includes a through-hole end caplocated between the second main body and the output end, and abubble-miniaturizing net located between the through-hole end cap andthe second main body. The water outlet member additionally includes aprojecting edge extending toward the output end from the through-holeend cap. The water outlet member further includes a water outlet chamberadjacent to the output end and connected to the second main body. Themicro-bubble generator further includes an eddy current guiding pipeprovided within the water outlet chamber, the eddy current guiding pipeincluding a plurality of blades in a spiral manner, a plurality of eddycurrent passages, wherein each of the plurality of eddy current passagesis arranged between two of the plurality of blades, and an outer casingtube surrounding the plurality of blades and the plurality of eddycurrent passages, a plurality of stepped surfaces being provided on asurface of each of the plurality of blades corresponding to each of theplurality of eddy current passages.

Furthermore, the first junction surface or the second junction surfaceis depressedly provided with a gasket groove, and the gasket groove isprovided therein with a gasket slightly projecting outside of the gasketgroove, the drop between the gasket and the gasket groove being providedto remain the gas inlet gap to the smallest extent when the firstjunction surface and the second junction surface are abutted againsteach other.

Furthermore, the micro-bubble generator further includes a regulatingpart, the regulating part including a regulating room constituted bycorresponding depressions in the first junction surface and the secondjunction surface, a regulating screw rod screwedly provided in theregulating room, and an inner thread screwedly threaded with theregulating screw rod. In addition, the regulating screw rod may be alsofixed in the regulating room by riveting.

Furthermore, the micro-bubble generator further includes aposition-limiting part, the position-limiting part including aposition-limiting room constituted by corresponding depressions in thefirst junction surface and the second junction surface, and aposition-limiting bolt movably provided in the position-limiting room,in which the regulating screw rod may be operated in a rotating mannerto change the depth of screw-threaded connection between the regulatingscrew rod and the inner thread, as well as drive the water inlet memberand the water outlet member to be far away from or close to each other.Moreover, the maximum extent to which the water inlet member and thewater outlet member are far away from each other is determined by theposition-limiting part.

Furthermore, the regulating part includes a regulating screw head movedalong with the regulating screw rod, a fixing ring fixing the regulatingscrew head to the inner wall of the regulating room, the fixing ringbeing openly provided with an operating through-hole allowing a toolpassing therethrough and operating the regulating screw head, and aplurality of water-passing holes allowing water stream passingtherethrough.

Furthermore, the water outlet member includes at least onebubble-multiplying part provided at one side, far away from the firstmain body, of the second main body, the bubble-multiplying partincluding a multiplying net and a spacing ring connected to themultiplying net.

It is another object of the present invention to provide a micro-bubblegenerator located between an input end and an output end of a wateroutlet device. The micro-bubble generator includes an accommodating partand a bubble-multiplying part. The accommodating part includes a firstaccommodating trough adjacent to the input end, a plurality ofaccommodating channels communicated with the first accommodating trough,and a second accommodating trough adjacent to the output end andcommunicated with each accommodating channel. The bubble-multiplyingpart includes a plurality of spacing rings concentrically providedwithin the second accommodating trough, and a plurality of multiplyingnets provided between the spacing rings, respectively.

The micro-bubble generator of the present invention may be mounted tothe water outlet of the faucet or the middle piping of the shower head,so as to generate a large amount of minute bubbles only by the force ofwater stream without the need for additional other power sources. Thedirection of inflow gas in the present invention is not restricted bythe drill hole, so as to obtain fragmental bubbles, which are more anddenser than those in the existing bubble generator, and further enhancethe effect of washing, sterilization and pesticide degradation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a disassembled perspective view of a micro-bubble generatorand a water outlet device of the present invention.

FIG. 2 is an assembled perspective view of a first embodiment of thepresent invention.

FIG. 3 is a disassembled perspective view of the first embodiment of thepresent invention.

FIG. 4 is a cross-sectional view of the first embodiment of the presentinvention.

FIG. 5 is a perspective view of an eddy current guiding pipe of thepresent invention.

FIG. 6 is an assembled perspective view of a second embodiment of thepresent invention.

FIG. 7 is a disassembled perspective view of the second embodiment ofthe present invention.

FIG. 8 is a cross-sectional view of the second embodiment of the presentinvention.

FIG. 9 is a cross-sectional view of a third embodiment of the presentinvention.

FIG. 10 is a disassembled perspective view of a fourth embodiment of thepresent invention.

FIG. 11A is an assembled perspective view of the fourth embodiment ofthe present invention.

FIG. 11B is a cross-sectional view along 11B-11B in FIG. 11A of thepresent invention.

FIG. 11C is a cross-sectional view along 11C-11C in FIG. 11A of thepresent invention.

FIG. 12A is a cross-sectional view of the fourth embodiment of thepresent invention.

FIG. 12B is an enlarged partial view of FIG. 12A of the presentinvention.

FIG. 13 is a disassembled perspective view of a fifth embodiment of thepresent invention.

FIG. 14 is an assembled perspective view of the fifth embodiment of thepresent invention.

FIG. 15A is a disassembled perspective view of a sixth embodiment of thepresent invention.

FIG. 15B is a cross-sectional view along 15B-15B in FIG. 15A of thepresent invention.

FIG. 16A is a disassembled perspective view of a seven embodiment of thepresent invention.

FIG. 16B is a cross-sectional view along 16B-16B in FIG. 16A of thepresent invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Regarding the technology of the present invention, referring to FIG. 1,the present invention provides a micro-bubble generator 100 a locatedbetween an input end 910 and an output end 920 of a water outlet device900, the water outlet device 900 probably being a shower head, faucetand so on. The micro-bubble generator 100 a may be provided inside theinterior piping of the water outlet device 900, or installed outside ofthe water outlet device 900 as illustrated in FIG. 1 without limitationin the present invention.

Specifically speaking, referring to FIGS. 2, 3 and 4, the micro-bubblegenerator 100 a includes a water inlet member 10 a and a water outletmember 20 a. The water inlet member 10 a includes a first main body 11 aadjacent to the input end 910, and a first channel 12 penetrating thefirst main body 11 a, the first main body 11 a being provided at one endpenetrated by the first channel 12 with a first junction surface 111.The water outlet member 20 a includes a second main body 21 a adjacentto the output end 920, and a second channel 22 penetrating the secondmain body 21 a. In this case, it is preferable that the aperture of thesecond channel 22 should be larger than that of the first channel 12slightly. The second main body 21 a is provided at one end penetrated bythe second channel 22 with a second junction surface 211. In thismanner, the water inlet member 10 a and the water outlet member 20 a areabutted against each other, with the first junction surface 111 facingthe second junction surface 211, the first channel 12 being communicatedwith the second channel 22, and the engagement between the firstjunction surface 111 and the second junction surface 211 remaining a gasinlet gap 30, the gas inlet gap 30 communicating external air to thefirst channel 12 and the second channel 22.

The gas inlet gap 30 is provided with a plurality of chiseled shallowrecesses 31 on the first junction surface 111 or the second junctionsurface 211, and it is necessary for each shallow recess 31 to passthrough two arbitrary points on the peripheral of the first junctionsurface 111 or the second junction surface 211. After the first junctionsurface 111 and the second junction surface 211 are joined face to face,slits formed by the shallow recesses 31 are then considered as the gasinlet gap 30. In addition, it is necessary for the gas inlet gap 30 topass through external air from joints between the first channel 12 andthe second channel 22, so as to enable external air to be communicatedto the first channel 12 and the second channel 22. On the boundary, anegative pressure is generated, so as to suck external air through thegas inlet gap 30 when the water stream flows into the second channel 22from the first channel 12 according to the above structure. Thus, theeffect of bubble generation due to liquid-gas mixing is achieved.

In this embodiment, the water inlet member 10 a includes a plurality offirst branching channels 13 a arranged alongside of the first channel12, while the water outlet member 20 a includes a plurality of secondbranching channels 23 a arranged alongside of the second channel 22. Inthis case, the aperture of the second branching channel 23 a ispreferably larger than that of each first branching channel 13 a, andthe engagement between the first branching channel 13 a and the secondbranching channel 23 a is communicated with the gas inlet gap 30. Eachfirst branching channel 13 a and each second branching channel 23 a arepreferably arranged to be respectively centered at the first channel 12and the second channel 22, for facilitating even suction of external airat various angles, such that gas inflow of liquid-gas mixing isincreased. In addition, the water inlet member 10 a, on one sideadjacent to the input end 910, includes a raised platform 14 penetratedby the first channel 12, and a notch 15 depressed around the raisedplatform 14 and penetrated by each first branching channel 13 a. Thewater stream flowing into each first branching channel 13 a isaccelerated so as to increase gas inflow due to the gradually narrowedcross-sectional area of the path, when the water stream flows throughthe notch 15.

Further, each first branching channel 13 a and/or each second branchingchannel 23 a may be respectively inclined with respect to the firstchannel 12 and the second channel 22, and preferably respectivelycentered at the first channel 12 and the second channel 22 to beinclined toward the center. In this way, after passing through eachsecond branching channel 23 a and the second channel 22, the waterstreams are disturbed by each other, so as to enhance the effect ofbubble collision and miniaturization.

The above-mentioned micro-bubble generator 100 a further includes asleeve 40 and an air vent perforation 50 penetrating the sleeve 40. Thewater inlet member 10 a and the water outlet member 20 a may be put intothe sleeve 40 and fixed, while the gas inlet gap 30 is communicated withthe air vent perforation 50. In addition, the first main body 11 a andthe second main body 21 a are provided, at one side connected to thesleeve 40, with a recess 112, 212, and a packing ring 113, 213 locatedwithin the recess 112, 212, respectively. Thereby, the first main body11 a and the second main body 21 a may be abutted against each other,while external air is allowed to flow into the boundary between thefirst junction surface 111 and the second junction surface 211 throughthe air vent perforation 50.

In addition, referring to FIG. 5, the above-mentioned micro-bubblegenerator 100 a further includes an eddy current guiding pipe 60 locatedat one end, adjacent to the second main body 21 a, of the sleeve 40, theeddy current guiding pipe 60 including a plurality of blades 61 in aspiral manner, a plurality of eddy current passages 62, wherein each ofthe plurality of eddy current passages 62 is arranged between two of theplurality of blades 61, and an outer casing tube 63 surrounding theplurality of blades 61 and the plurality of eddy current passages 62, aplurality of stepped surfaces 611 being provided on a surface of each ofthe plurality of blades 61 corresponding to each of the plurality ofeddy current passages 62. Each eddy current passage 62 formed by eachblade 61 is allowed to accelerate the water stream, while collisionforce generated by the collision of the water stream on each steppedsurface 611 is allowed to split gas-containing composition of wateragain into tinier bubbles, when the water stream flows through the wateroutlet member 20 a to the eddy current guiding pipe 60. The presentinvention may enable the water stream expelled from the water outletdevice 900 to contain a large amount of fine bubbles, and further, theenhancement of washing ability of discharged water, through the abovestructure.

In a second embodiment of the present invention, referring to FIGS. 6,7, and 8, each of the water inlet member 10 b and the water outletmember 20 b is in the form of a cylinder, respectively. The bottomsurface of the water inlet member 10 b is the first junction surface 111and the bottom surface of the water outlet member 20 b is the secondjunction surface 211. The water outlet member 20 b includes a wateroutlet chamber 24 adjacent to the output end 920 and connected to thesecond main body 21 b. The water outlet chamber 24 may be similarlyprovided therein with the aforementioned eddy current guiding pipe 60,so as to enhance gas content of discharged water and increase thefineness of bubble. In this embodiment, each first branching channel 13b, each second branching channel 23 b, the first channel 12 and thesecond channel 22 are all parallel to one another. In a thirdembodiment, referring to FIG. 9, each first branching channel 13 c andthe first channel 12 are parallel to each other, while each secondbranching channel 23 c and the second channel 22 are inclined toward thecenter, the merits of which are lower cost of manufacturing the mold,together with canted guidance of water stream for the generation ofdisturbance.

In addition, the water outlet member 20 c includes a through-hole endcap 241 located, correspondingly to the output end 920, in the secondmain body 21 c, and a bubble-miniaturizing net 242 located between thethrough-hole end cap 241 and the second main body 21 c. The through-holeend cap 241 is used for diverging the water stream so as to achieve,similarly to each first branching channel 13 c and each second branchingchannel 23 c, the effect of disturbance. The large-volume bubble may bedivided again into smaller bubbles, when the water stream passes throughthe bubble-miniaturizing net 242. In addition, the water outlet member20 c includes a projecting edge 243 extending toward the output end 920from the through-hole end cap 241. An action of guidance is provided bythe projecting edge 243 for guiding the water stream, when passingthrough the through-hole end cap 241, to flow along the axle center ofthe projecting edge 243.

In a fourth embodiment, referring to FIGS. 10, 11A, 11B, 11C, 12A and12B, the above-mentioned micro-bubble generator 100 d is depressedlyprovided, on either the first junction surface 111 or the secondjunction surface 211, with a gasket groove 16. In the gasket groove 16,a gasket 17 slightly projecting outside of the gasket groove 16 isprovided. Moreover, the drop between the gasket 17 and the gasket groove16 is provided to remain the gas inlet gap 30 to the smallest extentbetween the first junction surface 111 and the second junction surface211. In this embodiment, the gasket 17 is set as 1 mm in height.Specifically, the gasket 17 may be made of waterproof material withsufficient hardness, such as stainless steel and so on. Additionally,the gasket groove 16 is milled by a computer numerical control (CNC)machine tool to be a groove of 0.99 mm in height. Subsequently, thegasket 17 is placed, and the gas inlet gap 30 of 0.01 mm height is thenformed, so as to reduce the volume of bubble.

Referring to FIG. 11C to 12A again, the above-mentioned micro-bubblegenerator 100 d further includes a regulating part 70, the regulatingpart 70 including a regulating room 71 constituted by correspondingdepressions between the first junction surface 111 and the secondjunction surface 211, a regulating screw head 72 rotatably connected inthe regulating room 71, a regulating screw rod 73 passingly provided inthe regulating room 71 and moved along with the regulating screw head72, and an inner thread 74 located at the other end, opposite to theregulating screw head 72, of the regulating room 71, the regulatingscrew rod 73 being adjustably connected to the inner thread 74 by screwthreads. A user may be allowed to adjust the spacing between the wateroutlet member 20 d and the water inlet member 10 d through theregulating part 70, so as to open the gas inlet gap 30 and clearimpurities clogged in the gas inlet gap 30. Specifically, the regulatingscrew rod 73 may be riveted (not illustrated in the figures) at one endfar away from the regulating screw head 72, after combined with thewater outlet member 20 d and the water inlet member 10 d, such that theregulating screw rod 73 may be movable in a certain range based on theoperation of the user, but it is impossible to take out the regulatingscrew rod 73 as a whole. Further, the regulating part 70 includes afixing ring 75 fixing the regulating screw head 72 to the inner wall ofthe regulating room 71. The fixing ring 75 is openly provided with anoperating through-hole 751 allowing a tool passing therethrough andoperating the regulating screw head 72, and a plurality of water-passingholes 752 allowing the water stream passing therethrough. The firstchannel 12 may be provided at one side adjacent to the input end 910with a flow-guiding passage 121 converged toward the first channel 12,so as to increase the speed of water stream and raise the efficiency ofthe subsequent generation of bubbles.

In addition, the micro-bubble generator 100 d further includes aposition-limiting part 80, the position-limiting part 80 including aposition-limiting room 81 including corresponding depressions in thefirst junction surface 111 and the second junction surface 211, and aposition-limiting bolt 82 movably provided in the position-limiting room81. In this case, the regulating screw head 72 may be operated in arotating manner to change the depth of screw-threaded connection betweenthe regulating screw rod 73 and the inner thread 74, as well as drivethe water inlet member 10 d and the water outlet member 20 d to be faraway from or close to each other. Moreover, the maximum extent to whichthe water inlet member 10 d and the water outlet member 20 d are faraway from each other is determined by the position-limiting part 80. Inthis embodiment, the interior space of the position-limiting room 81 maybe provided for the position-limiting bolt 82 to be moved within acertain range. The object of the adjustment of the spacing between thewater inlet member 10 d and the water outlet member 20 d withoutdisconnecting these two members from each other may be obtained, if theposition-limiting room 81 is formed in a shape having one wider endtogether with the other narrower end, and the top of theposition-limiting bolt 82 is allowed to pass through the wider end whilestuck at the narrower end.

For further increasing the amount and the density of bubbles in thepresent invention, the water outlet member 20 d includes at least onebubble-multiplying part 26 provided at one side, far away from the firstmain body 11 d, of the second main body 21 d, the bubble-multiplyingpart 26 including a plurality of concentric spacing rings 262, and aplurality of multiplying nets 261 provided between the spacing rings262, respectively. Each spacing ring 262 and the second main body 21 dare closely fitted. The gas-liquid mixed liquid may be impacted todamage in the space, causing the separation provided by the spacing ring262, when passing through each multiplying net 261, so as to makebubbles more minute and dense. Additionally, the amount of bubbles isthen increased by cutting via another layer of multiplying net 261. Thespacing due to the separation provided by each spacing ring 262 isdependent on the apertures of water inlet and outlet of the water inletmember 10 d and the water outlet member 20 d without limitation herein.

Referring to FIGS. 13 and 14, there is shown a fifth embodiment of thepresent invention. In this case, the water inlet member 10 e of themicro-bubble generator 100 e is provided at the bottom thereof with anadapting screwed groove 18 in the form of threads. The adapting screwedgroove 18 may be connected to a water pipe having a joint, while thewater outlet member 20 e is connected to the water outlet device 900,such as shower head and so on, in such a way that a large amount ofbubbles are generated when water is discharged, so as to enhance theeffect of washing. In this embodiment, the water inlet member 10 e isprojectingly provided on the first junction surface 111 with anembossing gasket 19, the embossing gasket 19 being used for maintainingthe gas inlet gap 30 between the water inlet member 10 e and the wateroutlet member 20 e when the two members are abutted against each other.

Referring to FIGS. 15A and 15B, there is shown a sixth embodiment of thepresent invention. A micro-bubble generator A0 includes an accommodatingpart A1 and a bubble-multiplying part 26. The accommodating part A1includes a first accommodating trough A11 adjacent to the input end 910,a plurality of accommodating channels A12 communicated with the firstaccommodating trough A11, and a second accommodating trough A13 adjacentto the output end 920 and communicated with each accommodating channelA12. The bubble-multiplying part 26 includes the plurality of spacingrings 262 concentrically provided within the second accommodating troughA13, and the plurality of multiplying nets 261 provided between thespacing rings 262, respectively. In this embodiment, each spacing ring262 is preferably 0.2 to 1 mm in height, while the mesh size of eachmultiplying net 261 is in the range of 0.048 to 0.3 mm. The micro-bubblegenerator A0 may be suitable for the liquid containing air itself, suchas tap water and so on, according to the above structure. The object ofincreasing bubble density is further obtained by dividing and hittingair in water via the bubble-multiplying part 26.

In addition, referring to FIGS. 16A and 16B, there is shown a seventhembodiment of the present invention. This embodiment and the sixthembodiment are substantially the same, with the difference in that themicro-bubble generator A0 includes a plurality of air vent perforationsA14 communicating the exterior with each accommodating channel A12. Eachof the plurality of air vent perforations A14 is tapered in aperturefrom the exterior toward the accommodating channel A12 to be anextremely tiny gas hole. Furthermore, the accommodating channel A12includes an output channel A121 adjacent to the output end 920, and aninput channel A122 adjacent to the input end 910, wherein each of theplurality of air vent perforations A14 is communicated with the boundarybetween the output channel A121 and the input channel A122. The diameterof the input channel A122 is slightly smaller than that of the outputchannel A121, so as to generate Venturi effect.

What is claimed is:
 1. A micro-bubble generator provided between aninput end and an output end of a water outlet device, said micro-bubblegenerator comprising: a water inlet member, including a first main bodyadjacent to said input end, and a first channel penetrating said firstmain body, said first main body being provided at one end penetrated bysaid first channel with a first junction surface; and a water outletmember, including a second main body adjacent to said output end, and asecond channel penetrating said second main body, said second main bodybeing provided at one end penetrated by said second channel with asecond junction surface, wherein said water inlet member and said wateroutlet member are abutted against each other, with said first junctionsurface facing said second junction surface, said first channel beingcommunicated with said second channel, and one of said first junctionsurface and said second junction surface is provided with a plurality ofchiseled shallow recesses which forms a gas inlet gap after said firstjunction surface is engaged with said second junction surface, said gasinlet gap communicates external air to said first channel and saidsecond channel.
 2. The micro-bubble generator according to claim 1,wherein said water inlet member includes a plurality of first branchingchannels arranged alongside of said first channel, wherein said wateroutlet member includes a plurality of second branching channels arrangedalongside of said second channel, and an engagement between one of saidplurality of first branching channels and one of said plurality ofsecond branching channels is communicated with said gas inlet gap. 3.The micro-bubble generator according to claim 2, wherein said waterinlet member, on one side adjacent to said input end, includes a raisedplatform penetrated by said first channel, and a notch depressed aroundsaid raised platform and penetrated by each of said plurality of firstbranching channels.
 4. The micro-bubble generator according to claim 2,wherein each of said plurality of first branching channels and/or eachof said plurality of second branching channels may be inclined withrespect to said first channel and said second channel, respectively. 5.The micro-bubble generator according to claim 1, further comprising asleeve and an air vent perforation penetrating said sleeve, said waterinlet member and said water outlet member being put into said sleeve andfixed, while said gas inlet gap being communicated with said air ventperforation.
 6. The micro-bubble generator according to claim 5, furthercomprising an eddy current guiding pipe located at one end, adjacent tosaid second main body, of said sleeve, said eddy current guiding pipeincluding a plurality of blades in a spiral manner, a plurality of eddycurrent passages, wherein each of said plurality of eddy currentpassages is arranged between two of said plurality of blades, and anouter casing tube surrounding said plurality of blades and saidplurality of eddy current passages, a plurality of stepped surfacesbeing provided on a surface of each of said plurality of bladescorresponding to each of said plurality of eddy current passages.